Adjacent Gauche Stabilization in Linear Alkanes - American Chemical

Adjacent Gauche Stabilization in Linear Alkanes: Implications for Polymer Models and. Conformational Analysis. Jeffery B. Klauda,*,† Richard W. Past...
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15684

2005, 109, 15684-15686 Published on Web 07/30/2005

Adjacent Gauche Stabilization in Linear Alkanes: Implications for Polymer Models and Conformational Analysis Jeffery B. Klauda,*,† Richard W. Pastor,‡ and Bernard R. Brooks† Laboratory of Computational Biology, National Heart, Lung, and Blood Institute, National Institutes of Health, Bethesda, Maryland 20892-8014, and Laboratory of Biophysics, Center for Biologics EValuation and Research, FDA, 1401 RockVille Pike, RockVille, Maryland 20852-1448 ReceiVed: May 25, 2005; In Final Form: June 29, 2005

High-level ab initio quantum mechanical calculations are used to study various gauche conformational energies of n-pentane to n-decane. The destabilizing “pentane effect” (adjacent gauche states of opposite sign) for alkanes is confirmed, but the energies were found to depend slightly on chain length. In contrast, introducing an adjacent gauche of the same sign requires only 0.22-0.37 kcal/mol, approximately half of the single gauche state energy. This adjacent gauche stabilization should be taken into account when formulating or analyzing rotational isomeric models, carrying out conformational analysis, and developing force fields for alkanes, lipids, and related polymers.

The modeling of intra- and intermolecular interactions of alkanes is important not only for hydrocarbon research but also for polymers and biological compounds such as lipids. For polymer research, the rotational isomeric state (RIS) model was developed by Flory in 1969.1 The fundamental parameter of the RIS model is ∆Eg, the energy difference between the trans (t) and gauche (g); this is 0.5 kcal/mol for alkanes. This energy is assumed to be additive for all gauche states other than g+gpairs, which have energy substantially higher than 2 × ∆Eg; this destabilization is called the “pentane effect” and is primarily steric in origin.1,2 Organic chemists more commonly refer to the effect as “syn-pentane interaction”, and recognize its importance in conformational analysis.3 High-level ab initio quantum mechanical (QM) calculations on pentane through heptane yields a ∆Eg slightly higher than 0.5 kcal/mol,4-6 while ∆Eg+g+ is lower than 2 × ∆Eg. Atomic force fields, such as CHARMM27 (C27),7,8 agree with the QM calculations and indicate that long-range attractions in the g+g+ (equivalently, g-g-) states stabilize adjacent gauche conformations.6 Klauda et al.6 termed this stabilization the “positive pentane effect” (to contrast the destabilizing pentane effect). In this letter, a more extensive set of calculations is reported to further characterize the effect and to help determine its implications for polymer and lipid modeling. We have renamed this behavior “adjacent gauche stabilization” (AGS) for increased clarity. Pentane was used as a test case to determine the optimal QM theory and basis set for optimizations and conformational energy calculations. The Guassian03 suite of programs9 was used for all QM calculations. Conformational minima were optimized using tight convergence criteria (1.5 × 10-4 and 1.0 × 10-4 * To whom correspondence should be addressed. E-mail: klauda@ helix.nih.gov. † National Institutes of Health. ‡ Federal Department of Agriculture.

10.1021/jp0527608

TABLE 1: ∆Ei in kcal/mol (single point energy// optimization) for Pentane with DZ ) cc-pVDZ and TZ ) cc-pVTZ conf.

MP2/TZ// MP2/DZ

CCSD(T)/TZ// MP2/DZ

%Error MP2

CCSD(T)/TZ// CCSD/DZ

tg g+g+ g+g-

0.56 0.80 2.81

0.59 0.93 2.78

+5.1 +14.0 -1.1

0.59 0.95 2.79

hartree/bohr for maximum and RMS force, respectively) and a starting structure near the corresponding geometry. Previously it was found that geometry optimizations with MP2/cc-pVDZ were superior to those with density functional theory.6 The effect of basis set was minimal, but higher level QM and g+g+ and g+g- conformations were not tested. Consequently, we performed optimizations that compared results at CCSD/cc-pVDZ and MP2/cc-pVDZ for the tt, tg, g+g+, and g+g- conformations of pentane. The carbon-carbon bond lengths were nearly identical for CCSD and MP2, and only a slight increase was obtained in the carbon angles (approximately 0.3°) for the higher level calculation. The minima for g-, t, and g+ states are close to -60°, 180°, and 60°, respectively, and are usually independent of the values of neighboring dihedrals. The exception is g+g-, where g+ = 60° and g- = -90°. There was negligible difference for the t state dihedrals and on average only a 0.6° deviation for the g dihedrals. These slight variations in geometry are important to our work only if they affect the relative energy of conformation i with respect to the all-trans state, ∆Ei. For these energy calculations, CCSD(T) is required to reduce the underestimate of the MP2 g+ minima.6 This is evident in Table 1, where the largest deviations between MP2 and CCSD(T) occur for the adjacent gauche states, and MP2 overestimates the AGS by 14%. The differences for the conformational energies with geometries optimized at MP2/cc-pVDZ and CCSD/cc-pVDZ are small, less than 0.02 kcal/mol. The slight deviations

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Published 2005 by the American Chemical Society

Letters

J. Phys. Chem. B, Vol. 109, No. 33, 2005 15685

TABLE 2: MP2:CC ∆Ei Energy in kcal/mol, where (g+)m for the First Alkane in a Column and t(g+)mtn-m-4 for n Alkane Carbons alkane

m)1

n)4 5 6 7 8 9 10

0.63 0.62 0.60 0.56 0.54 0.54 0.54

2 0.99 0.93 0.87 0.82 0.80 0.80

3

1.27 1.19 1.09 1.04 1.02

4

1.54 1.45 1.36 1.31

5

1.81 1.72 1.62

6

2.06 1.97

7

TABLE 3: MP2:CC ∆Ei Energy in kcal/mol, where i ) (g+)mg- for the First Alkane in the Column and t(g+)mg-tn-m-5 for n Alkane Carbons alkane

m)1

2

3

4

5

6

n)5 6 7 8 9 10

2.85 2.74 2.54 2.51 2.49 2.49

3.12 2.95 2.70 2.61 2.59

3.48 3.39 3.17 3.11

3.74 3.65 3.43

3.99 3.90

4.24

2.32

in geometries have a negligible effect on ∆Ei. Therefore, all conformational geometries are optimized with MP2/ cc-pVDZ. The CCSD(T) results in Table 1 provide strong support for AGS in pentane. Since CCSD(T) calculations with basis sets larger than cc-pVTZ are intractable, even for a small alkane like pentane, an alternative approach is required to obtain an estimate of the CCSD(T) energy with a large basis set (LBS). One such method assumes that the differences in energies for the large and small basis sets (SBS) are the same for MP2 and CCSD(T),10-13 and CCSD(T)/LBS energy is estimated as follows:

E[CCSD(T)/LBS] = E[CCSD(T)/SBS] + (E[MP2/LBS] - E[MP2/SBS]) (1) Klauda et al.10 determined that the differences between energies using eq 1 with a LBS of cc-pVQZ and cc-pV5Z were negligible and near the basis set limit (SBS ) cc-pVDZ). In addition, the approximate CCSD(T)/cc-pVQZ energy differences for butane using eq 1 are accurate within about 1-2% from the CCSD(T) energy differences with a nearly complete basis set.6 The errors in the conformational energies associated with an incomplete basis set and optimization at a lower level of theory are at most (0.04 kcal/mol. Therefore, all energies reported in subsequent tables use eq 1 with SBS ) cc-pVDZ and LBS ) cc-pVQZ and are denoted MP2:CC.10 The conformational energies of single and adjacent g+ states for normal alkanes from butane to decane are listed in Table 2. On the diagonal of Table 2 are the all-g+ conformations for each alkane. For the other conformations, there is one trans state at the beginning of the chain and then m g+ dihedrals, with the remaining carbon dihedrals as trans. As evident from Table 2, there is a strong chain length dependence of ∆Ei for the shorter alkanes, i.e., a 14% reduction in the gauche energy from butane to octane. However, the dependence of ∆Eg on the chain length becomes negligible for alkanes larger than octane. There is a 19-20% reduction for states with two and three adjacent g+ states. Long-range intramolecular dispersion stabilizes these gauche states.10 The significant stabilization that occurs for conformations with adjacent gauche states is the focus of this work. In RIS model ∆Eg is independent of its neighboring torsional state, but clearly from Table 2 this assumption is incorrect. Once a chain is “seeded” with a single gauche state at the cost of 0.54-0.62 kcal/mol, the energy of adding an adjacent gauche of the same sign is only 0.22-0.37 kcal/mol. The stabilization effect is negligible for alkane conformations with g+ states that are separated by a dihedral, especially for larger alkanes. This was tested for tg+tg+tn-7 conformations of hexane to decane. For hexane, the effective ∆Eg per gauche state, 〈∆Eg〉, is 0.59 kcal/mol with a slight stabilization compared

Figure 1. Terms for eq 2 (RIS-like model) obtained from MP2:CC energies.

to ∆Etgt, but the 〈∆Eg〉 for the staggered gauche state of decane is identical to that in Table 2 (0.54 kcal/mol). The final set of QM calculations listed in Table 3 is for adjacent gauche conformations with a single g- state at the end, t(g+)mg-tn-m-5, where n is the number of carbons in the alkane and m is the number of g+ states. As with the pure g+ configurations, there is moderate chain length stabilization for the configurations in Table 3, e.g., 13% reduction in ∆Eg+gfrom pentane to nonane. However, the ∆Etg+g-tn-5 appears to reach an asymptote for alkanes larger than nine carbons. The QM results indicate that an additional adjacent gauche state correction term is required for the RIS model. The total energy of an alkane or saturated polymer can be modeled as

E(total) ) ng∆Eg + ng+g-AGD + ng+g+AGS

(2)

where the number of gauche and pairs of g+g- and g+g+ in a chain are ng, ng+g-, and ng+g+, respectively. The adjacent gauche destabilization (AGD) or “pentane effect” is the additional energy required for a single adjacent g- state. The new term, AGS, in eq 2 is the stabilization energy for each g+g+ pair in a chain. In the RIS model by Flory,1 the ∆Eg effectively includes AGS and, consequently, ∆Eg is slightly smaller than the values in Table 2. The RIS model also assumes that the curvature for each conformational minimum is equal, so that the statistical weights are equal for all minima. The MP2:CC curvatures of the tttt, tgtt, and tg+g+t minima of heptane are 1.9 × 10-3, 3.2 × 10-3, and 4.0 × 10-3 kcal/(mol deg2), respectively.6 The curvature increase for each gauche state is about 1 × 10-3 kcal/(mol deg2), which suggests that further refinements to the RIS model should include different statistical weights. The terms in eq 2 are shown in Figure 1 as a function of the hydrocarbon chain length. The value for AGS for each alkane of length n was obtained from eq 2 with the corresponding energies in Table 2 using root-mean-squared (RMS) fits to all g+g+ conformations. AGD was obtained similarly from Table 3. There is only a small chain length dependence on the AGS and ADG energies (3.4% reduction from pentane to decane).

15686 J. Phys. Chem. B, Vol. 109, No. 33, 2005 The average AGS and AGD over all alkanes is -0.26 and +1.56 kcal/mol, respectively. Atomic force fields used in molecular simulation partially include AGS with the attractive intramolecule long-range dispersion via the 6-12 Lennard-Jones (LJ) potential. However, these LJ parameters are typically fit to reproduce intermolecular interactions and phase behavior. AGS is not consistently taken into account in force fields such as C27 and C27r (revised C27 to best fit a subset of alkane QM calculations presented here).6 For example, C27r calculated ∆Ei for decane with tg+t5, t(g+)2t4, t(g+)3t3, and (g+)7 conformations deviate from MP2:CC by 0.02, 0.14, 0.31, and 0.99 kcal/mol, respectively. In conclusion, the assumption that ∆Eg is independent of neighboring dihedrals in the RIS model is invalid. This is evident in Figure 1 and Table 2 where significant stabilization exists for adjacent gauche states of the same sign. The energies of gauche states depend on the chain length for small alkanes, though the AGS is relatively independent of chain length. Force fields should reproduce energies presented here, especially AGS, to obtain accurate populations of conformational states in polymers and lipids. Acknowledgment. Some of the QM calculations utilized the high-performance computational capabilities of the Biowulf PC/ Linux cluster at the National Institutes of Health, Bethesda, Maryland (http://biowulf.nih.gov). References and Notes (1) Flory, P. J. Statistical Mechanics of Chain Molecules; John Wiley & Sons: New York, 1969.

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